CN218686116U - High-low oxygen training equipment driving circuit and high-low oxygen training equipment - Google Patents

Abstract

The utility model provides a high-low oxygen training device driving circuit and a high-low oxygen training device.A human-computer interface device receives a working signal and outputs the working signal to the input end of an industrial personal computer through a first signal transmission device; the industrial personal computer receives the working signal, generates a control signal and outputs the control signal to the input end of the main control circuit board through the second signal transmission device; the main control circuit board is used for receiving the control signal, generating a first driving signal and outputting the first driving signal to a first relay circuit connected with the compressor, and generating a second driving signal and outputting the second driving signal to a second relay circuit connected with the nitrogen-oxygen separation device; each sensor generates a feedback signal and outputs the feedback signal to the input end of the main control circuit board; the output end of the main control circuit board outputs a feedback signal to the input end of the industrial personal computer through the second signal transmission device. The utility model provides high hypoxemia training equipment drive circuit's operational capability and signal processing ability are favorable to realizing hypoxemia training equipment function diversification.

Description

High-low oxygen training equipment driving circuit and high-low oxygen training equipment

Technical Field

The utility model relates to a high hypoxemia training equipment technical field, concretely relates to high hypoxemia training equipment drive circuit and high hypoxemia training equipment.

Background

At present, intermittent high-oxygen and low-oxygen training is proved by medicine and physiology, has obvious improvement effects on hypertension, hyperlipidemia, arteriosclerosis, myocardial function, hematopoietic capability and human brain cognition of partial crowds, and can be used for improving the functions of a human body, and enhancing the immune system, the nonspecific compensation capability and the aerobic output of the human body.

Intermittent type nature high hypoxemia training method needs to use high hypoxemia training equipment, and prior art's high hypoxemia training equipment drive circuit's operational capability is poor, can't be fine carry out signal processing, can't realize high hypoxemia training equipment function diversification, leads to high hypoxemia training equipment function singleness.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model provides a high hypoxia training device drive circuit and high hypoxia training device, the concrete technical scheme is as follows:

a high-low oxygen training equipment driving circuit comprises a human-computer interface device, an industrial personal computer, a main control circuit board, a compressor, a nitrogen-oxygen separation device, a blood oxygen sensor, an oxygen concentration sensor, a gas flow sensor and a gas pressure sensor;

the human-computer interface device is used for receiving a working instruction and generating a working signal, and the output end of the human-computer interface device is output to the input end of the industrial personal computer through the first signal transmission device;

the industrial personal computer is used for receiving the working signal and generating a control signal, and the output end of the industrial personal computer outputs the control signal to the input end of the main control circuit board through a second signal transmission device;

the main control circuit board is connected with the compressor through a first relay circuit, the main control circuit board is connected with the nitrogen-oxygen separation device through a second relay circuit, and the main control circuit board is used for receiving the control signal, generating a first driving signal and outputting the first driving signal to the first relay circuit, and generating a second driving signal and outputting the second driving signal to the second relay circuit;

the blood oxygen sensor, the oxygen concentration sensor, the gas flow sensor and the gas pressure sensor are used for generating feedback signals and outputting the feedback signals to the input end of the main control circuit board;

and the output end of the main control circuit board outputs the feedback signal to the input end of the industrial personal computer through the second signal transmission device.

In a specific embodiment, the control circuit board further comprises a proportional valve, the main control circuit board is connected with the proportional valve through a seventh signal transmission device, and the main control circuit board is further configured to receive the control signal, generate a third driving signal and output the third driving signal to the proportional valve through the seventh signal transmission device.

In a specific embodiment, the industrial personal computer is further configured to receive the feedback signal and generate a display signal, and an output end of the industrial personal computer outputs the display signal to an input end of the human-computer interface device through a first signal transmission device.

In one embodiment, the blood oxygen sensor outputs a feedback signal to the main control circuit board through a third signal transmission device;

the oxygen concentration sensor outputs a feedback signal to the main control circuit board through a fourth signal transmission device;

the gas flow sensor outputs a feedback signal to the main control circuit board through a fifth signal transmission device;

and the gas pressure sensor outputs a feedback signal to the main control circuit board through a sixth signal transmission device.

In a specific embodiment, the device further comprises one or more combinations of a heart rate sensor, a blood pressure sensor, an electrocardiogram detector, a temperature sensor, a respiratory rate sensor and a tidal volume detector;

the heart rate sensor outputs a feedback signal to the main control circuit board through an eighth signal transmission device;

the blood pressure sensor outputs a feedback signal to the main control circuit board through a ninth signal transmission device;

the electrocardiogram detector outputs a feedback signal to the main control circuit board through a tenth signal transmission device;

the temperature sensor outputs a feedback signal to the main control circuit board through an eleventh signal transmission device;

the respiratory frequency sensor outputs a feedback signal to the main control circuit board through a twelfth signal transmission device;

and the tidal volume detector outputs a feedback signal to the main control circuit board through a thirteenth signal transmission device.

In a specific embodiment, the system further comprises a remote controller, wherein the remote controller is used for sending a working signal and outputting the working signal to the input end of the industrial personal computer through a wireless communication circuit.

In a specific embodiment, still include the voice broadcast ware, the industrial computer is still used for receiving the working signal generates the voice broadcast signal, the output of industrial computer passes through the voice broadcast circuit output the voice broadcast signal extremely the voice broadcast ware.

In a specific embodiment, the industrial personal computer further comprises an alarm, the industrial personal computer is further used for receiving the feedback signal and generating an alarm signal, and the output end of the industrial personal computer outputs the alarm signal to the alarm through an alarm circuit.

In a particular embodiment, the alarm comprises a flashing alarm and/or an audio alarm.

A high-low oxygen training device comprises the high-low oxygen training device driving circuit.

In a specific embodiment, the human-computer interface device is arranged on the industrial personal computer; or the main control circuit board is arranged on the industrial personal computer.

The utility model discloses following beneficial effect has at least:

the utility model discloses a high-low oxygen training equipment driving circuit, which comprises a human-computer interface device, an industrial personal computer, a main control circuit board, a compressor, a nitrogen-oxygen separation device, a blood oxygen sensor, an oxygen concentration sensor, a gas flow sensor and a gas pressure sensor; the human-computer interface device is used for receiving the working instruction and generating a working signal, and the output end of the human-computer interface device is output to the input end of the industrial personal computer through the first signal transmission device; the industrial personal computer is used for receiving the working signal and generating a control signal, and the output end of the industrial personal computer outputs the control signal to the input end of the main control circuit board through the second signal transmission device; the main control circuit board is connected with the compressor through a first relay circuit, connected with the nitrogen-oxygen separation device through a second relay circuit, and used for receiving control signals, generating first driving signals and outputting the first driving signals to the first relay circuit, and generating second driving signals and outputting the second driving signals to the second relay circuit; the blood oxygen sensor, the oxygen concentration sensor, the gas flow sensor and the gas pressure sensor are used for generating feedback signals and outputting the feedback signals to the input end of the main control circuit board; the output end of the main control circuit board outputs a feedback signal to the input end of the industrial personal computer through the second signal transmission device. The utility model discloses an industrial computer that operational capability is stronger carries out signal processing, has improved high hypoxemia training equipment drive circuit's operational capability and signal processing ability, is favorable to realizing that the function of high hypoxemia training equipment is diversified.

Further, a high-low oxygen training device is provided, including high-low oxygen training device drive circuit, improve the degree of cooperation between each subassembly, the user of being convenient for uses, has improved user experience and has felt.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a first structural diagram of the high-hypoxia training device driving circuit provided in example 1;

fig. 2 is a second structural diagram of the driving circuit of the hyperhypoxic training apparatus provided in embodiment 1;

fig. 3 is a third structural diagram of the high hypoxia training device driving circuit provided in example 1;

fig. 4 is a first structural diagram of the high-hypoxia training device provided in example 2;

fig. 5 is a second structural diagram of the high-hypoxia training device provided in example 2;

fig. 6 is a third structural diagram of the high hypoxia training device provided in example 2.

Reference numerals:

1-a human-machine interface device; 2-an industrial personal computer; 3-a master control circuit board; 4-a compressor; 5-nitrogen-oxygen separation device; 6-a proportional valve; 7-a blood oxygen sensor; 8-an oxygen concentration sensor; 9-gas flow sensor; 10-a gas pressure sensor; 11-first signal transmission means; 12-second signal transmission means; 13-third signal transmission means; 14-fourth signal transmission means; 15-fifth signal transmission means; 16-sixth signal transmission means; 17-a first relay circuit; 18-a second relay circuit; 19-a remote controller; 20-wireless communication circuitry; 21-voice broadcasting device; 22-voice broadcast circuit; 23-an alarm; 24-an alarm circuit; 25-seventh signal transmission means; 25-a housing; 31-a heart rate sensor; 32-eighth signal transmission means; 33-a blood pressure sensor; 34-ninth signal transmission means; 35-an electrocardiography detector; 36-tenth signal transmission means; 37-a temperature sensor; 38-eleventh signal transmission means; 39-respiratory rate sensor; 40-twelfth signal transmission means; 41-tidal volume detector; 42-thirteenth signal transmission means.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "vertical", "upper", "lower", "horizontal", and the like indicate the directions or positional relationships based on the directions or positional relationships shown in the drawings, which are only for the convenience of describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a specific direction, be constructed and operated in a specific direction, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

Example 1

As shown in fig. 1, the present embodiment provides a high-low oxygen training device driving circuit, which includes a human-computer interface device 1, an industrial personal computer 2, a main control circuit board 3, a compressor 4, a nitrogen-oxygen separation device 5, a proportional valve 6, a blood oxygen sensor 7, an oxygen concentration sensor 8, a gas flow sensor 9, and a gas pressure sensor 10.

As shown in fig. 1, a first signal transmission device 11 is arranged between the output end of the human-computer interface device 1 and the input end of the industrial personal computer 2. The human-computer interface device 1 is used for receiving work orders and generating work signals. The human-machine interface device 1 displays preset working instructions (such as turning on or off the compressor 4, turning on or off the nitrogen-oxygen separation device 5, etc.), a user inputs the working instructions through the human-machine interface device 1, and the human-machine interface device 1 detects the working instructions input by the user and generates corresponding working signals based on the working instructions. The human-computer interface device 1 outputs the working signal to the industrial personal computer 2 through the first signal transmission device 11 so as to realize the signal transmission between the human-computer interface device 1 and the industrial personal computer 2.

Specifically, the human-machine interface device 1 is preferably a touch display screen, but is not limited thereto.

Specifically, the first signal transmission device 11 is RS232, RS485, RS422.

Specifically, the nitrogen-oxygen separation device 5 includes a molecular sieve device or an oxygen-rich membrane device.

As shown in fig. 1, a second signal transmission device 12 is disposed between the industrial personal computer 2 and the main control circuit board 3. The industrial personal computer 2 is used for receiving the working signal input by the human-computer interface device 1, generating a control signal and outputting the control signal to the main control circuit board 3 through the second signal transmission device 12, so that signal transmission between the industrial personal computer 2 and the main control circuit board 3 is realized.

As shown in fig. 1, a first relay circuit 17 is provided between the output end of the main control board 3 and the compressor 4, and a second relay circuit 18 is provided between the output end of the main control board 3 and the nitrogen-oxygen separation device 5. After receiving the control signal through the second signal transmission device 12, the main control circuit board 3 generates a first driving signal acting on the first relay circuit 17 and a second driving signal acting on the second relay circuit 18 based on the control signal.

The output end of the main control circuit board 3 outputs a first driving signal to the first relay circuit 17, the first relay circuit 17 is turned on or off according to the received first driving signal, and the air compressor 3 starts to work or stops working.

The output end of the main control circuit board 3 outputs a second driving signal to the second relay circuit 18, the second relay circuit 18 closes or opens the second relay circuit 18 according to the received second driving signal, and the nitrogen-oxygen separation device 5 starts to work or stops working.

As shown in fig. 2, the driving circuit further includes a proportional valve 6, a seventh signal transmission device 25 is disposed between the proportional valve 6 and the main control circuit board 3, and the main control circuit board 3 is configured to generate a third driving signal based on the control signal after receiving the control signal. The output end of the main control circuit board 3 outputs a third driving signal to the proportional valve 6 through the seventh signal transmission device 25, and the proportional valve 6 adjusts the working mode according to the received third driving signal.

As shown in fig. 1 and 2, the blood oxygen sensor 7 is in contact with the user for measuring the blood oxygen level or the oxygen saturation in the blood of the user and converting the detection result into the blood oxygen feedback signal. The third signal transmission device 13 is used for receiving the feedback signal output by the signal acquisition board in the blood oxygen sensor 7 and outputting the feedback signal to the main control circuit board 3.

An oxygen concentration sensor 8, a gas flow sensor 9 and a gas pressure sensor 10 are arranged at the exhaust port of the high-low oxygen training device. The oxygen concentration sensor 8 is used for measuring the concentration of oxygen in the exhaust gas of the exhaust port of the high-hypoxia training equipment and converting the measurement result into an oxygen concentration feedback signal. The fourth signal transmission device 14 is used for receiving the feedback signal output by the signal acquisition board in the oxygen concentration sensor 8 and outputting the feedback signal to the main control circuit board 3.

The gas flow sensor 9 is used for measuring the flow of gas in the exhaust gas of the exhaust port of the high-low oxygen training device and converting the detection result into a gas flow feedback signal. The fifth signal transmission device 15 is used for receiving the feedback signal output by the signal acquisition board in the gas flow sensor 9 and outputting the feedback signal to the main control circuit board 3.

The gas pressure sensor 10 is used for measuring the pressure of the gas discharged from the exhaust port of the hyperhypoxic training apparatus, and converting the measurement result into a gas pressure feedback signal. The sixth signal transmission device 16 is configured to receive the feedback signal output by the signal acquisition board in the gas pressure sensor 10 and output the feedback signal to the main control circuit board 3.

As shown in fig. 2, the industrial personal computer 2 receives feedback signals of the blood oxygen sensor 7, the oxygen concentration sensor 8, the gas flow sensor 9 and the gas pressure sensor 10 collected by the main control circuit board 3 through the second signal transmission device 12.

A first signal transmission device 11 is arranged between the industrial personal computer 2 and the human-computer interface device 1. The industrial personal computer 2 receives feedback signals of the blood oxygen sensor 7, the oxygen concentration sensor 8, the gas flow sensor 9 and the gas pressure sensor 10 output by the main control circuit board 3, analyzes and processes the feedback signals to generate display signals, and the display signals are transmitted to the human-computer interface device 1 through the first signal transmission device 11. The interactivity between the industrial personal computer 2 and the human-computer interface device 1 is increased, and the user experience is improved.

Specifically, the industrial personal computer 2 generates a display signal after analyzing and processing the feedback signal, and the human-computer interface device 1 receives the display signal and generates a respiration training oscillogram according to the display signal. For example, a breathing training waveform diagram with the oxygen concentration value as the abscissa and the blood oxygen value of the user as the ordinate is convenient for the user to observe.

The utility model discloses a make industrial computer 2 receive the working signal of 1 output of human-computer interface device to according to the work of 3 drive compressors 4 of working signal control main control circuit board and nitrogen oxygen separator 5, know user's state and the gaseous state of output of high low oxygen training equipment through the feedback signal of industrial computer 2 through blood oxygen sensor 7, oxygen concentration sensor 8, gas flow sensor 9 and gas pressure sensor 10. The utility model discloses an industrial computer 2 that the operational capability is stronger carries out signal processing, has improved high hypoxemia training equipment drive circuit's operational capability and signal processing ability, is favorable to realizing that the function of high hypoxemia training equipment is diversified.

As shown in fig. 2, the remote control system further comprises a remote controller 19, the remote controller 19 is connected with the industrial personal computer 2 through a wireless communication circuit 20, and the remote controller 19 generates a working signal under the operation of a user and outputs the working signal to the input end of the industrial personal computer 2 through the wireless communication circuit 20. The way that the user sends the work instruction is increased, the user can control the driving circuit through the human-computer interface device 1 and the remote controller 19, the application range is expanded, and the user experience is improved.

Specifically, the remote controller 19 is preferably a remote controller, a cell phone, or the like.

As shown in fig. 2, still include voice broadcast ware 21, be provided with voice broadcast circuit 22 between industrial computer 2 and the voice broadcast ware 21, industrial computer 2 receives behind the working signal based on the working signal generates the voice broadcast signal, and industrial computer 2's output passes through voice broadcast circuit 22 and outputs voice broadcast signal to voice broadcast ware 21, carries out voice broadcast after voice broadcast ware 21 receives. For example, industrial computer 2 receives "open compressor 4" behind the working signal generate "open compressor 4" the voice broadcast signal based on this working signal, and industrial computer 2's output passes through voice broadcast circuit 22 and outputs this voice broadcast signal to voice broadcast ware 21, and voice player 21 plays "open compressor 4" the pronunciation. The voice player 21 indicates the operation state of the high-low oxygen training device, so that the user can know the operation state of the high-low oxygen training device, and meanwhile, the voice player has a reminding function, and the user is prevented from outputting wrong operation instructions.

As shown in fig. 2, the industrial personal computer 2 further comprises an alarm 23, the industrial personal computer 2 is connected with the alarm 23 through an alarm circuit 24, the industrial personal computer 2 receives the feedback signal and then analyzes and processes the feedback signal, when the feedback signal reaches an early warning value, an alarm signal is generated, and an output end of the industrial personal computer 2 outputs the alarm signal to the alarm 23 through the alarm circuit 24. Increase alarming function, when the dangerous condition appears, can in time remind the user, reduce the possibility of accident, it is intelligent high.

Specifically, the alarm 23 includes a flashing alarm and/or an audio alarm. When the feedback signal reaches the warning value, the flashing alarm flashes and/or the audio alarm sounds to attract the attention of the user.

Example 2

As shown in fig. 3, one or more combinations of a heart rate sensor 31, a blood pressure sensor 33, an electrocardiograph detector 35, a temperature sensor 37, a respiratory rate sensor 39, and a tidal volume detector 41 are also included.

The heart rate sensor 31 is used for detecting the number of heart beats per minute of the user and converting the detection result into a heart beat feedback signal. The eighth signal transmission device 32 is configured to receive a feedback signal output by a signal acquisition board in the heart rate sensor 31 and output the feedback signal to the main control circuit board 3.

The blood pressure sensor 33 is used for detecting the blood pressure of the user and converting the detection result into a blood pressure feedback signal. The ninth signal transmission device 34 is used for receiving the feedback signal output by the signal acquisition board in the blood pressure sensor 33 and outputting the feedback signal to the main control circuit board 3.

The electrocardiograph detector 35 is used for detecting the electrocardiographic activity of the user and converting the detection result into an electrocardiographic feedback signal. The tenth signal transmission device 36 is used for receiving the feedback signal output by the signal acquisition board in the electrocardiograph detector 35 and outputting the feedback signal to the main control circuit board 3.

The temperature sensor 37 is disposed at the air outlet of the high-low oxygen training device, and is configured to detect the temperature of the air outlet and convert the detection result into a temperature feedback signal. The eleventh signal transmission device 38 is configured to receive the feedback signal output by the signal acquisition board in the temperature sensor 37 and output the feedback signal to the main control circuit board 3.

The breathing frequency sensor 39 is disposed at the exhalation end of the user, and is used for detecting the breathing frequency of the user and converting the detection result into a breathing frequency feedback signal. The twelfth signal transmission device 40 is configured to receive the feedback signal output by the signal acquisition board in the respiratory rate sensor 39 and output the feedback signal to the main control circuit board 3.

The tidal volume detector 41 is disposed at the exhalation end of the user, and is configured to detect the tidal volume of the user and convert the detection result into a tidal volume feedback signal. The thirteenth signal transmission device 42 is configured to receive the feedback signal output by the signal acquisition board in the tidal volume detector 41 and output the feedback signal to the main control circuit board 3.

As shown in fig. 3, the industrial personal computer 2 receives feedback signals of the heart rate sensor 31, the blood pressure sensor 33, the electrocardiogram detector 35, the temperature sensor 37, the respiratory rate sensor 39 and the tidal volume detector 41 collected by the main control circuit board 3 through the second signal transmission device 12.

The industrial personal computer 2 receives the feedback signals of the heart rate sensor 31, the blood pressure sensor 33, the electrocardiogram detector 35, the temperature sensor 37, the respiratory rate sensor 39 and the tidal volume detector 41 output by the main control circuit board 3, analyzes and processes the feedback signals to generate a display signal, and transmits the display signal to the human-computer interface device 1 through the first signal transmission device 11. The interactivity between the industrial personal computer 2 and the human-computer interface device 1 is increased, and the user experience is improved.

Example 3

The present embodiment provides a high-hypoxia training device, which includes the high-hypoxia training device driving circuits described in embodiments 1 and 2. The adaptability between the industrial personal computer 2 and the human-computer interface device 1, the main control circuit board 3, the compressor 4, the nitrogen-oxygen separation device 5, the blood oxygen sensor 7, the oxygen concentration sensor 8, the gas flow sensor 9 and the gas pressure sensor 10 is improved, the use by a user is facilitated, and the user experience is improved.

As shown in fig. 4, 5 and 6, the human-computer interface device 1 is disposed on a housing 25 of the high and low oxygen training device, the industrial personal computer 2, the main control circuit board 3, the compressor 4 and the nitrogen-oxygen separation device 5 are disposed in the housing 25, wherein the main control circuit board 3 is disposed on the industrial personal computer 2.

Alternatively, the human-machine interface device 1 may be disposed on the industrial personal computer 2 in other embodiments.

Those skilled in the art will appreciate that the drawings are merely schematic representations of one preferred implementation scenario and that the blocks or flow diagrams in the drawings are not necessarily required to practice the present invention.

Those skilled in the art will appreciate that the modules in the devices in the implementation scenario may be distributed in the devices in the implementation scenario according to the description of the implementation scenario, or may be located in one or more devices different from the present implementation scenario with corresponding changes. The modules of the implementation scenario may be combined into one module, or may be further split into a plurality of sub-modules.

The utility model discloses the serial number is only for the description, does not represent the goodness of implementing the scene.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the present invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included within the protection scope of the present invention.

Claims (10)

1. A high-low oxygen training equipment driving circuit is characterized by comprising a human-computer interface device, an industrial personal computer, a main control circuit board, a compressor, a nitrogen-oxygen separation device, a blood oxygen sensor, an oxygen concentration sensor, a gas flow sensor and a gas pressure sensor;

the human-computer interface device is used for receiving a working instruction and generating a working signal, and the output end of the human-computer interface device is output to the input end of the industrial personal computer through the first signal transmission device;

the industrial personal computer is used for receiving the working signal and generating a control signal, and the output end of the industrial personal computer outputs the control signal to the input end of the main control circuit board through a second signal transmission device;

the main control circuit board is connected with the compressor through a first relay circuit, the main control circuit board is connected with the nitrogen-oxygen separation device through a second relay circuit, and the main control circuit board is used for receiving the control signal, generating a first driving signal and outputting the first driving signal to the first relay circuit, and generating a second driving signal and outputting the second driving signal to the second relay circuit;

the blood oxygen sensor, the oxygen concentration sensor, the gas flow sensor and the gas pressure sensor are used for generating feedback signals and outputting the feedback signals to the input end of the main control circuit board;

and the output end of the main control circuit board outputs the feedback signal to the input end of the industrial personal computer through the second signal transmission device.

2. The high-and-low-oxygen training device driving circuit according to claim 1, further comprising a proportional valve, wherein the main control circuit board is connected to the proportional valve through a seventh signal transmission device, and the main control circuit board is further configured to receive the control signal and generate a third driving signal, and output the third driving signal to the proportional valve through the seventh signal transmission device.

3. The high-low oxygen training device driving circuit according to claim 1, wherein the industrial personal computer is further configured to receive the feedback signal and generate a display signal, and an output end of the industrial personal computer outputs the display signal to an input end of the human-computer interface device through the first signal transmission device.

4. The high-hypoxia training device driving circuit according to claim 1, wherein the blood oxygen sensor outputs a feedback signal to the main control circuit board through a third signal transmission device;

the oxygen concentration sensor outputs a feedback signal to the main control circuit board through a fourth signal transmission device;

the gas flow sensor outputs a feedback signal to the main control circuit board through a fifth signal transmission device;

and the gas pressure sensor outputs a feedback signal to the main control circuit board through a sixth signal transmission device.

5. The high-hypoxia training device driving circuit according to claim 1, further comprising one or more combinations of a heart rate sensor, a blood pressure sensor, an electrocardiogram detector, a temperature sensor, a respiratory rate sensor, and a tidal volume detector;

the heart rate sensor outputs a feedback signal to the main control circuit board through an eighth signal transmission device;

the blood pressure sensor outputs a feedback signal to the main control circuit board through a ninth signal transmission device;

the electrocardiogram detector outputs a feedback signal to the main control circuit board through a tenth signal transmission device;

the temperature sensor outputs a feedback signal to the main control circuit board through an eleventh signal transmission device;

the respiratory frequency sensor outputs a feedback signal to the main control circuit board through a twelfth signal transmission device;

and the tidal volume detector outputs a feedback signal to the main control circuit board through a thirteenth signal transmission device.

6. The high-low oxygen training device driving circuit according to claim 1, further comprising a remote controller, wherein the remote controller is used for sending a working signal and outputting the working signal to an input end of the industrial personal computer through a wireless communication circuit.

7. The high-low oxygen training device driving circuit according to claim 1, further comprising a voice broadcast device, wherein the industrial personal computer is further configured to receive the working signal and generate a voice broadcast signal, and an output end of the industrial personal computer outputs the voice broadcast signal to the voice broadcast device through a voice broadcast circuit.

8. The high-hypoxia training device driving circuit according to claim 1, further comprising an alarm, wherein the industrial personal computer is further configured to receive the feedback signal and generate an alarm signal, and an output end of the industrial personal computer outputs the alarm signal to the alarm through an alarm circuit.

9. Hypoxia-training-device driver circuit according to claim 8, wherein the alarm comprises a flashing alarm and/or an audio alarm.

10. High-hypoxia training device, comprising the high-hypoxia training device driving circuit according to any one of claims 1 to 9.

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